IE4503 – Chapter 2
Time Value of Money (Money-
Time Relationships)
2
Objective
Given a cash flow (or series of cash flows)
occurring at some point in time, the
objective is to find its equivalent value at
another point in time considering the time
value of money.
3
Time Value of Money
$100 today or $120 one year from now?
Why does money have a time value?
What affects money’s time value (i.e.
interest rate)?
Two Ways for Calculating the Time-Value
of Money:
1. Simple Interest
2. Compound Interest
4
Simple Interest
The amount of interest earned (or paid) is
directly proportional to the principal of the
loan, the number of interest periods for
which the principal is committed, and the
interest rate per period.
5
Simple Interest Example
Borrow $1000 for 5 yrs. at 12% interest/yr.
(1) (2) = P x 12% (3)=(1)+(2)
Period
(year)
Amount Owed at
Beginning of Period
Interest Amount
for Period
Amount Owed at
End of Period
1 $ 1,000 $ 120 $ 1,120
2 $ 1,120 $ 120 $ 1,240
3 $ 1,240 $ 120 $ 1,360
4 $ 1,360 $ 120 $ 1,480
5 $ 1,480 $ 120 $ 1,600
$ 600
6
Compound Interest
The amount of interest earned (or paid)
per interest period depends on the
remaining principal of the loan plus any
unpaid interest charges.
7
Compound Interest Example
borrow $1000 for 5 yrs. at 12% interest/yr.
(1) (2) = (1) x 12% (3)=(1)+(2)
Period
(year)
Amount Owed at
Beginning of Period
Interest Amount
for Period
Amount Owed at
End of Period
1 $ 1,000.00 $ 120.00 $ 1,120.00
2 $ 1,120.00 $ 134.40 $ 1,254.40
3 $ 1,254.40 $ 150.53 $ 1,404.93
4 $ 1,404.93 $ 168.59 $ 1,573.52
5 $ 1,573.52 $ 188.82 $ 1,762.34
$ 762.34
8
Equivalence Example
Amount of Principal = $ 8000
Interest rate = 10% /yr.
Duration of the loan = 4 years
Consider two different payment plans to see the meaning of equivalence.
Plan1: At the end of each year pay $2000 principal plus interest due.
Plan2: Pay principal and interest in one payment at the end of four years.
9
Plan1: At the end of each year pay $2000 principal
plus interest due
(1) (2) (3)=0.1x(2) (4)=(2)+(3) (5) (6)=(3)+(5)
Year
Amount
owed at
beginning
of year
Interest
Accrued
for year
Total Money
Owed at end
of year
Principal
payment
Total
End-of-Year
payment
(Cash Flow)
1 $ 8000 $ 800 $ 8800 $ 2000 $ 2800
2 6000 600 6600 2000 2600
3 4000 400 4400 2000 2400
4 2000 200 2200 2000 2200
$ 20,000 $ 2000 total
dollar-years
total
interest
$ 8000 $ 10,000 total amount
repaid
10
Plan2: Pay principal and interest in one payment at
the end of four years
(1) (2) (3)=0.1x(2) (4)=(2)+(3) (5) (6)=(3)+(5)
Year
Amount
owed at
beginning
of year
Interest
Accrued
for year
Total Money
Owed at end
of year
Principal
payment
Total
End-of-Year
payment
(Cash Flow)
1 $ 8000 $ 800 $ 8800 $0 $0
2 8800 880 9680 0 0
3 9680 968 10,648 0 0
4 10,648 1065 11,713 8000 11,713
$ 37,130 $ 3713 total
dollar-years
total
interest
$ 8000 $ 11,713 total amount
repaid
11
Comparison of Plans 1 & 2 Summing the amount owed at the beginning of
each year yields the amount of money "rented" in
dollar-years.
Plan Dollar-years Total Interest
Paid
Ratio of Total Interest
to Dollar-Years
1 $ 20,000 $2,000 0.10
4 $ 37,130 $3,713 0.10
Equivalence is established when total interest paid,
divided by dollar-years of borrowing, is a constant ratio
among financing plans.
12
Cash Flow Diagrams (CFDs)
Use a consistent viewpoint
13
Cash Flows of Plans 1 & 2 from
Borrower’s viewpoint
Plan 1 Plan 2
EOY Cash Flows Cash Flows
0 $ 8000 $8000
1 – 2800 0
2 – 2600 0
3 – 2400 0
4 – 2200 – 11,713
14
Cash Flow Diagrams of Plans 1 & 2
from Borrower’s viewpoint
Plan 1 Plan 2
EOY = End - of -Year
15
Cash Flows of Plans 1 & 2 from
Lender’s viewpoint Plan 1 Plan 2
EOY Cash Flows Cash Flows
0 – $ 8000 – $8000
1 2800 0
2 2600 0
3 2400 0
4 2200 11,713
16
Cash Flow Diagrams of Plans 1 & 2
from Lender’s viewpoint
Plan 1 Plan 2
EOY = End - of -Year
17
Interest Formulas Relating to
Single Cash Flows
1. How to find the Future Equivalent value
of a Present Sum of Money
2. How to find the Present Equivalent value
of a Future Sum of Money
18
Single Payment Compound
Amount Factor
The quantity (1+i)N in the equation is commonly
called the single payment compound amount
factor.
Numerical values for this factor have been
calculated for a wide range of values of i and N,
and they are available in the tables of Appendix C
(1+i)N = (F / P, i%, N)
F = P (F / P, i%, N)
19
Example for finding F given P
F=?
0 1 2 3 4 5 6 7 8
P = 1000
F8 = P (F/P, 10%, 8) = 1000 (2.1436)
Solution :
= $2143.6
A firm borrows $1000 for eight years at i = 10%. How much must it repay in a lump sum at the end of eighth year?
20
How to find the Present Equivalent
value of a Future Sum of Money
F = P(1+i)N
P = F [1 / (1+i)N] = F(1+i) – N
21
Single Payment Present Worth
Factor
The quantity (1+i) – N in the equation is commonly
called the single payment present worth factor.
Numerical values for this factor have been
calculated for a wide range of values of i and N,
and they are available in the tables of Appendix C.
(1+i) –N = (P / F, i%, N)
P = F (P / F, i%, N)
22
Example for finding P given F
How much would you have to deposit now into an
account paying 10% interest per year in order to have
$1,000,000 in 40 years?
Assumptions:
Constant interest rate; no additional deposits or withdrawals
P = $1000,000 (P/F, 10%, 40) = $22,100 0.0221
Solution:
23
Timing relationships for P, A and F
24
Finding F When Given A
We could treat each A as a separate present sum:
F = A(1+i) N-1 + A(1+i) N-2 + A(1+i) N-3 + ...+A(1+i) 1 + A(1+i) 0
i
iAF
N 1)1(
Given a uniform series of
payments, A, for N periods,
how might we determine
the equivalent future sum,
F, at t = N?
This equation can be reduced to:
25
Uniform Series Compound
Amount Factor
i
i N 1)1(
is the uniform series compound
amount factor
i
i N 1)1(= (F / A, i%, N)
F = A (F / A, i%, N)
26
Example for finding F given A
Assume you make 10 equal annual deposits of $2,000
into an account paying 5% per year. How much is in the
account just after the 10th deposit?
F= $2,000 (F/A, 5%, 10) 12.5779
= $25,156
Solution
27
Finding P When Given A
i
iAiP
NN 1)1(
)1(
We could treat each A as a separate future sum:
P = A(1+i) -1 + A(1+i) -2 + A(1+i) -3 + ...+A(1+i) – (N-1) + A(1+i) – N
If we wish to withdraw a
uniform sum (A) for N
years from an account
paying i% interest, how
much must we deposit
now (P)?
or
N
N
ii
iAP
)1(
1)1(
28
Uniform Series Present Worth
Factor
N
N
ii
i
)1(
1)1(is the uniform series present worth factor
N
N
ii
i
)1(
1)1( = (P / A, i%, N)
P = A (P / A, i%, N)
29
Example for finding P given A If a certain machine undergoes a major overhaul now,
its output can be increased by 20% – which translates
into additional cash flow of $20,000 at the end of each
year for five years. If i=15% per year, how much can
we afford to invest to overhaul this machine?
P = $20,000 (P/A, 15%, 5) 3.3522
= $67,044
Solution
30
Finding A When Given F
i
i
FA
i
iAF
N
N
1)1(
1)1(
Given a future sum of
money, F, how might we
determine the equivalent
uniform end-of-period
series, A, for N periods?
1)1( Ni
iF
31
Uniform Series Sinking Fund
Factor
1)1( Ni
iis the uniform series sinking fund factor ■
1)1( Ni
i= (A / F, i%, N) ■
A = F (A / F, i%, N) ■
32
Example finding A given F
Recall that you would need to deposit $22,100 today into an
account paying 10% per year in order to have $1,000,000 40
years from now. Instead of the single deposit, what uniform
annual deposit for 40 years would also make you a
millionaire?
A = $1,000,000 (A/F, 10%, 40) = $2,300 0.0023
Solution
33
Finding A When Given P
N
NN
N
ii
i
PA
ii
iAP
)1(
1)1()1(
1)1(
Given a present sum of
money, P, how might we
determine the equivalent
uniform end-of-period
series, A, for N periods?
1)1(
)1(N
N
i
iiP
34
Uniform Series Capital
Recovery Factor
1)1(
)1(N
N
i
iiis the uniform series capital recovery factor
1)1(
)1(N
N
i
ii= (A / P, i%, N)
A = P (A / P, i%, N)
35
Example for finding A given P
Suppose you finance a $10,000 car over 60 months at an
interest rate of 1% per month. How much is your monthly
car payment?
Lender's POV:
0.0222
A = $10,000 (A/P, 1%, 60) = $222 per month
Solution
36
Deferred Annuities If we are looking for a present (future) equivalent sum at
time other than one period prior to the first cash flow in the
series (coincident with the last cash flow in the series) then
we are dealing with a deferred annuity.
37
Deferred Annuities for finding P
P = A (P/A, i%, N – J)(P/F, i%, J)
Dealing with a
deferred annuity
when looking for a
present equivalent
sum:
38
Example: Deferred Annuities for
Present Equivalent Sum
How much do you need to deposit today into an account
that pays 3% per year so that you can make 10 equal
annual withdrawals of $1,000, with the first withdrawal
being made seven years from now?
39
Solution
P0=P6 (P/F, 3%, 6) = $8,530.20(0.8375) = $7,144
P6=$1,000(P/A, 3%, 10) = $1000(8.5302) = $8,530.20
40
Deferred Annuities for finding F
F = A(F/A, i%, J)(F/P, i%, N – J)
Dealing with a
deferred annuity
when looking
for a future
equivalent sum:
41
Example: Deferred Annuities for
Future Equivalent Sum
Assume you make 10 equal annual deposits of $2,000
into an account paying 5% per year. How much is in the
account 5 years after the last deposit?
42
Solution
F15 = F10 (F/P, 5%, 5) = $25,156(1.2763) = $32,106.6
F10 = $2000(F/A, 5%, 10) = $2000(12.5779) = $25,156
43
Multiple Interest Factors
Some situations include multiple unrelated
sums or series, requiring the problem be
broken into components that can be
individually solved and then re-integrated.
44
Example: Multiple Interest Factors
Given:
Find: P0, F6, F7, A1 – 6
45
Solution for P0
P0 = 800 (P/A, 10%, 3)(P/F, 10%, 3) + 500 (P/A, 10%, 3)
– 1000 (P/F, 10%, 3)
0.7513 2.4869
P0 = ?
2.4869
0.7513 = $1987
$1987
46
Solution for F6
F6 = 800 (F/A, 10%, 3) + 500 (F/A, 10%, 3)(F/P, 10%, 3)
– 1000 (F/P, 10%, 3) 1.331
3.31 3.31 1.331
= $3,520
F6= ?
$3,520
47
Alternative Solution for F6
$1987
F6= ?
$3,520
F6 = $1987 (F/P, 10%, 6) = $3,520
48
Solution for F7
F6 = 800 (F/A, 10%, 3) + 500 (F/A, 10%, 3)(F/P, 10%, 3)
– 1000 (F/P, 10%, 3) = $3,520
1.1
F7= ?
$3,872
F7 = 3,520 (F/P, 10%, 1)
F6
= $3,872
49
Solution procedure for finding Annuity of a
given multiple cash flows
1) Convert into a single cash flow form
or
2) Convert into annuity form
50
Solution for A1-6
A1-6 = F6 (A/F, 10%, 6)
A1-6= ?
= 3520 (0.1296) = $456
$456 $456 $456 $456 $456 $456
= $456
51
Finding N Given P, F and i
F = P (1+i)N
N log (1+i) = log (F/P)
N = log (F/P) / log (1+i)
F = P (F/P, i%, N)
(F/P, i%, N) = F/P
N is found from
interest table
or
52
Finding N Given F, A and i
)1log(
)log(1
log
i
iiA
F
N
F = A (F/A, i%, N)
(F/A, i%, N) = F/A or
N is found from
interest table
53
Finding N Given P, A and i
)1log(
)log(1
log
)1(i
iA
P
iN
P = A (P/A, i%, N)
(P/A, i%, N) = P/A or
N is found from
interest table
54
Example 2.7
Suppose that your rich uncle has $1000,000 that he
wishes to distribute to his heirs at the rate of
$100,000 per year. If the $1000,000 is deposited in a
bank account that earns 6% interest per year, how
many years will it take to completely deplete the
account?
55
Example 2.7 (solution)
)06.1log(
)06.0log(1006.0
1log
)1()1log(
)log(1
log
)1( Ni
iA
P
iN
N = 15.7 years 16 years
56
Finding i, Given P, F and N
(1+i)N = F / P
1 N
P
Fi
F = P(1+i)N
57
Example 2.8
Suppose you borrowed $8,000 now and the lender
wants $11,713 to be paid 4 years from now, what is
the interest rate accrued on your debt?
1.18000
11713)1( 4 i
i = 1.1 -1 = 0.1 = 10%
11713 = 8000 (1+i)4
Solution
58
Interest rates that vary with time
Find the present equivalent value given a future value and
a varying interest rate over the period of the loan
N
k
ki
FP
1
)1(
Using single (average) interest rate for compounding /
discounting the single cash flows:
1)1()1()1(11
N
N
k
k
N
k
k
N iiii
59
Example 2.9
A person has made an arrangement to borrow $1000 now
and another $1000 two years hence. The entire obligation is
to be paid at the end of four years. If the projected interest
rates in years one, two, three and four are 10%, 12%, 12%,
and 14%, respectively, how much will be repaid as a lump-
sum amount at the end of four years?
60
Example 2.9 (solution)
F1 = 1000(F/P, 10%, 1) = $1100
F2 = 1100(F/P, 12%, 1) + 1000 = $2,232
F3 = 2232(F/P, 12%, 1) = $2,500
F4 = 2500(F/P, 14%, 1) = $2,849.8
61
Uniform Gradient Series
What if we have cash flows (revenues or expenses) that are projected to increase or decrease by a uniform amount each period? (e.g. maintenance costs, rental income)
We call this a uniform gradient series (G)
We can have positive or negative gradients if the slope of the cash flows is positive or negative, respectively
62
CFDs of Uniform Gradient Series
Positive Gradient Negative Gradient
63
Finding A When Given G
Given a uniform gradient series for N periods, G, how might
we determine the equivalent uniform end-of-period series,
A, for N periods?
1)1(
1Ni
N
iGA = gradient to uniform series conversion factor
A = G (A / G, i%, N)
64
Finding P When Given G Given a uniform gradient series for N periods, G, how
might we determine the equivalent present sum at t=0?
NN
N
i
N
ii
i
iGP
)1()1(
1)1(1
P = G (P / G, i%, N)
= gradient to present equivalent
conversion factor
65
Positive Gradient Example
Given:
Find: P0 and A1 – 8
66
Solution procedure
G = $100 in the above example.
G = constant by which the cash flows increase or
decrease each period.
67
Solution for P0
P0 = $250 (P/A, 10%, 8) + $100 (P/G, 10%, 8)
16.029 5.3349
= $2,937
68
Solution for A1-8
A1-8 = $250 + 100 (A/G, 10%, 8)
3.0045
= $550.45
69
Negative Gradient Example
Given:
Find:
Equivalent values for these cash flows at: P0 and A1-5
70
Solution procedure
The gradient is negative (e.g., an increasing cost) and the
uniform series is positive (e.g., steady stream of revenue).
G = – 250 Underlying annuity (A) = +1250
71
Solution for P0
P0 = 1,250(P/A, 10%, 5) - 250(P/G, 10%, 5)
3.7908 6.86
= $3,023.5
72
Solution for A1-5
A1-5 = 1,250 - 250(A/G, 10%, 5) 1.8101
= $797.48
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